Difference between revisions of "Life support"

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On [[Mars]] we will not be able to maintain a life support system that needs consumables. The alternative is a near-natural [[carbon cycle]] with the growing of [[food]] and producing [[oxygen]] at the same time.
 
On [[Mars]] we will not be able to maintain a life support system that needs consumables. The alternative is a near-natural [[carbon cycle]] with the growing of [[food]] and producing [[oxygen]] at the same time.
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The challenge is the day and night rhythm as well as the lasting [[dust storms]]. Oxygen can only produced with light, either [[sunlight]] or [[lighting|artificial light]]. During the night or during a dust storm there is not enough sunlight, neither for direct lighting for the plants nor for [[photovoltaics|photovoltaic]] powered [[electricity|electric]] light. The [[Biosphere 2]] experiment has shown significant deviations from good oxygen conditions due to the day and night rhythm.
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The first Martian settlement will probably be much smaller than Biosphere 2, making it even harder to keep a constant oxygen level. This article discusses solutions to mitigate this issue.
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=== Buffering of the gases ===
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Big tanks of [[water]] may be used to buffer some amount of oxygen as well as [[CO2|CO<sub>2</sub>]], since those gases are soluble in water according to [https://en.wikipedia.org/wiki/Henry's_law Henry's law]. A good side effect is the heat capacity of the water, helping to keep a comfortable temperature in the settlement.
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=== Constant artificial lighting ===
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Parts of the oxygen producing [[greenhouse]]s may be lit at night, which requires [[energy storage|stored electrical energy]]. The stored energy must be large enough to cover a few months of dust storms, whereas [[wind turbine]]s may help to produce part of the needed energy.
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==Open Issues==
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* What is necessary to build such a water buffer? How much water is needed? How can the active surface of the water be extended (rinsing over lava stone, spraying in the air, etc.) and what amount of energy is needed to keep this technology running?
  
 
[[Category: Human Considerations]]
 
[[Category: Human Considerations]]
 
[[Category: Greenhouse]]
 
[[Category: Greenhouse]]

Revision as of 07:30, 30 October 2015

Live support systems are an essential and necessary part of a Martian settlement, since the natural Martian environment does not allow human beings to survive.

ISS-like systems

The life support system on the ISS is optimized to low weight. It must be fuelled with large amounts of energy and it requires a constant replenishment with consumables.

Near-natural systems

On Mars we will not be able to maintain a life support system that needs consumables. The alternative is a near-natural carbon cycle with the growing of food and producing oxygen at the same time.

The challenge is the day and night rhythm as well as the lasting dust storms. Oxygen can only produced with light, either sunlight or artificial light. During the night or during a dust storm there is not enough sunlight, neither for direct lighting for the plants nor for photovoltaic powered electric light. The Biosphere 2 experiment has shown significant deviations from good oxygen conditions due to the day and night rhythm.

The first Martian settlement will probably be much smaller than Biosphere 2, making it even harder to keep a constant oxygen level. This article discusses solutions to mitigate this issue.

Buffering of the gases

Big tanks of water may be used to buffer some amount of oxygen as well as CO2, since those gases are soluble in water according to Henry's law. A good side effect is the heat capacity of the water, helping to keep a comfortable temperature in the settlement.

Constant artificial lighting

Parts of the oxygen producing greenhouses may be lit at night, which requires stored electrical energy. The stored energy must be large enough to cover a few months of dust storms, whereas wind turbines may help to produce part of the needed energy.

Open Issues

  • What is necessary to build such a water buffer? How much water is needed? How can the active surface of the water be extended (rinsing over lava stone, spraying in the air, etc.) and what amount of energy is needed to keep this technology running?